// g2o - General Graph Optimization
// Copyright (C) 2011 R. Kuemmerle, G. Grisetti, W. Burgard
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright notice,
//   this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above copyright
//   notice, this list of conditions and the following disclaimer in the
//   documentation and/or other materials provided with the distribution.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

#include "graph_optimizer_sparse_online.h"

#include <iostream>

#include "g2o/core/block_solver.h"
#include "g2o/core/optimization_algorithm_factory.h"
#include "g2o/core/optimization_algorithm_gauss_newton.h"
#include "g2o/solvers/cholmod/linear_solver_cholmod.h"  // IWYU pragma: keep
#include "g2o/solvers/pcg/linear_solver_pcg.h"
#include "g2o/stuff/macros.h"
#include "types_slam2d_online.h"
#include "types_slam3d_online.h"

using namespace std;
using namespace Eigen;

namespace g2o {

namespace {
template <int p, int l>
std::unique_ptr<g2o::Solver> AllocatePCGSolver() {
  std::cerr << "# Using PCG online poseDim " << p << " landMarkDim " << l
            << " blockordering 1" << std::endl;

  auto linearSolver = std::make_unique<
      LinearSolverPCG<typename BlockSolverPL<p, l>::PoseMatrixType>>();
  linearSolver->setMaxIterations(6);
  return std::make_unique<BlockSolverPL<p, l>>(std::move(linearSolver));
}
}  // namespace

// force linking to the cholmod solver
G2O_USE_OPTIMIZATION_LIBRARY(cholmod);

SparseOptimizerOnline::SparseOptimizerOnline(bool pcg)
    : SparseOptimizer(),
      slamDimension(3),
      newEdges(0),
      batchStep(true),
      vizWithGnuplot(false),
      _gnuplot(0),
      _usePcg(pcg),
      _underlyingSolver(0) {}

SparseOptimizerOnline::~SparseOptimizerOnline() {
  if (_gnuplot) {
#ifdef WINDOWS
    _pclose(_gnuplot);
#else
    pclose(_gnuplot);
#endif
  }
}

int SparseOptimizerOnline::optimize(int iterations, bool online) {
  // return SparseOptimizer::optimize(iterations, online);

  (void)iterations;  // we only do one iteration anyhow
  OptimizationAlgorithm* solver = _algorithm;

  bool ok = true;

  solver->init(online);
  if (!online) {
    ok = _underlyingSolver->buildStructure();
    if (!ok) {
      G2O_ERROR("Failure while building CCS structure");
      return 0;
    }
  }

  if (_usePcg) batchStep = true;

  if (!online || batchStep) {
    // cerr << "BATCH" << endl;
    //_underlyingSolver->buildStructure();
    //  copy over the updated estimate as new linearization point
    if (slamDimension == 3) {
      for (size_t i = 0; i < indexMapping().size(); ++i) {
        OnlineVertexSE2* v = static_cast<OnlineVertexSE2*>(indexMapping()[i]);
        v->setEstimate(v->updatedEstimate);
      }
    } else if (slamDimension == 6) {
      for (size_t i = 0; i < indexMapping().size(); ++i) {
        OnlineVertexSE3* v = static_cast<OnlineVertexSE3*>(indexMapping()[i]);
        v->setEstimate(v->updatedEstimate);
      }
    }

    SparseOptimizer::computeActiveErrors();
    // SparseOptimizer::linearizeSystem();
    _underlyingSolver->buildSystem();
  } else {
    // cerr << "UPDATE" << endl;
    //  compute the active errors for the required edges
    for (HyperGraph::EdgeSet::iterator it = newEdges->begin();
         it != newEdges->end(); ++it) {
      OptimizableGraph::Edge* e = static_cast<OptimizableGraph::Edge*>(*it);
      e->computeError();
    }
    // linearize the constraints and update the Hessian
    for (HyperGraph::EdgeSet::iterator it = newEdges->begin();
         it != newEdges->end(); ++it) {
      OptimizableGraph::Edge* e = static_cast<OptimizableGraph::Edge*>(*it);
      e->linearizeOplus(jacobianWorkspace());
      e->constructQuadraticForm();
    }
    // update the b vector
    for (int i = 0; i < static_cast<int>(indexMapping().size()); ++i) {
      OptimizableGraph::Vertex* v = indexMapping()[i];
      int iBase = v->colInHessian();
      v->copyB(_underlyingSolver->b() + iBase);
    }
  }
  ok = _underlyingSolver->solve();
  update(_underlyingSolver->x());

  if (verbose()) {
    computeActiveErrors();
    cerr << "nodes = " << vertices().size()
         << "\t edges= " << _activeEdges.size()
         << "\t chi2= " << FIXED(activeChi2()) << endl;
  }

  if (vizWithGnuplot) gnuplotVisualization();

  if (!ok) return 0;
  return 1;
}

void SparseOptimizerOnline::update(double* update) {
  if (slamDimension == 3) {
    for (size_t i = 0; i < _ivMap.size(); ++i) {
      OnlineVertexSE2* v = static_cast<OnlineVertexSE2*>(_ivMap[i]);
      v->oplusUpdatedEstimate(update);
      update += 3;
    }
  } else if (slamDimension == 6) {
    for (size_t i = 0; i < _ivMap.size(); ++i) {
      OnlineVertexSE3* v = static_cast<OnlineVertexSE3*>(_ivMap[i]);
      v->oplusUpdatedEstimate(update);
      update += 6;
    }
  }
}

bool SparseOptimizerOnline::updateInitialization(HyperGraph::VertexSet& vset,
                                                 HyperGraph::EdgeSet& eset) {
  newEdges = &eset;
  bool result = SparseOptimizer::updateInitialization(vset, eset);
  for (HyperGraph::VertexSet::iterator it = vset.begin(); it != vset.end();
       ++it) {
    OptimizableGraph::Vertex* v = static_cast<OptimizableGraph::Vertex*>(*it);
    v->clearQuadraticForm();  // be sure that b is zero for this vertex
  }
  return result;
}

bool SparseOptimizerOnline::initSolver(int dimension, int /*batchEveryN*/) {
  slamDimension = dimension;
  OptimizationAlgorithmFactory* solverFactory =
      OptimizationAlgorithmFactory::instance();
  OptimizationAlgorithmProperty solverProperty;
  if (_usePcg) {
    std::unique_ptr<Solver> s;
    if (dimension == 3) {
      s = AllocatePCGSolver<3, 2>();
    } else {
      s = AllocatePCGSolver<6, 3>();
    }

    OptimizationAlgorithmGaussNewton* gaussNewton =
        new OptimizationAlgorithmGaussNewton(std::move(s));
    setAlgorithm(gaussNewton);
  } else {
    if (dimension == 3) {
      setAlgorithm(
          solverFactory->construct("gn_fix3_2_cholmod", solverProperty));
    } else {
      setAlgorithm(
          solverFactory->construct("gn_fix6_3_cholmod", solverProperty));
    }
  }

  OptimizationAlgorithmGaussNewton* gaussNewton =
      dynamic_cast<OptimizationAlgorithmGaussNewton*>(solver());
  _underlyingSolver = &gaussNewton->solver();

  if (!solver()) {
    cerr << "Error allocating solver. Allocating CHOLMOD solver failed!"
         << endl;
    return false;
  }
  return true;
}

void SparseOptimizerOnline::gnuplotVisualization() {
  if (slamDimension == 3) {
    if (!_gnuplot) {
#ifdef WINDOWS
      _gnuplot = _popen("gnuplot -persistent", "w");
#else
      _gnuplot = popen("gnuplot -persistent", "w");
#endif
      if (_gnuplot == 0) return;
      fprintf(_gnuplot, "set terminal X11 noraise\n");
      fprintf(_gnuplot, "set size ratio -1\n");
    }
    fprintf(_gnuplot, "plot \"-\" w l\n");
    for (EdgeSet::iterator it = edges().begin(); it != edges().end(); ++it) {
      OnlineEdgeSE2* e = static_cast<OnlineEdgeSE2*>(*it);
      OnlineVertexSE2* v1 = static_cast<OnlineVertexSE2*>(e->vertices()[0]);
      OnlineVertexSE2* v2 = static_cast<OnlineVertexSE2*>(e->vertices()[1]);
      fprintf(_gnuplot, "%f %f\n", v1->updatedEstimate.translation().x(),
              v1->updatedEstimate.translation().y());
      fprintf(_gnuplot, "%f %f\n\n", v2->updatedEstimate.translation().x(),
              v2->updatedEstimate.translation().y());
    }
    fprintf(_gnuplot, "e\n");
  }
  if (slamDimension == 6) {
    if (!_gnuplot) {
#ifdef WINDOWS
      _gnuplot = _popen("gnuplot -persistent", "w");
#else
      _gnuplot = popen("gnuplot -persistent", "w");
#endif
      if (_gnuplot == 0) return;
      fprintf(_gnuplot, "set terminal X11 noraise\n");
    }
    fprintf(_gnuplot, "splot \"-\" w l\n");
    for (EdgeSet::iterator it = edges().begin(); it != edges().end(); ++it) {
      OnlineEdgeSE3* e = (OnlineEdgeSE3*)*it;
      OnlineVertexSE3* v1 = static_cast<OnlineVertexSE3*>(e->vertices()[0]);
      OnlineVertexSE3* v2 = static_cast<OnlineVertexSE3*>(e->vertices()[1]);
      fprintf(_gnuplot, "%f %f %f\n", v1->updatedEstimate.translation().x(),
              v1->updatedEstimate.translation().y(),
              v1->updatedEstimate.translation().z());
      fprintf(_gnuplot, "%f %f %f \n\n\n",
              v2->updatedEstimate.translation().x(),
              v2->updatedEstimate.translation().y(),
              v2->updatedEstimate.translation().z());
    }
    fprintf(_gnuplot, "e\n");
  }
}

}  // namespace g2o
